DE4227213C2 - Switch lock for a circuit breaker - Google Patents

Abstract

The latching mechanism for power circuit breakers is the force-storing binding element between the handle and a contact apparatus. The production cost of previous latching mechanisms is excessively high. Furthermore, in the event of contact welding, there is a risk of the contact apparatus not opening despite the latching mechanism being released. The new latching mechanism (10) reliably opens the contact apparatus and consists of a smaller number of individual parts (components) which are of technologically simpler design. It is inserted between two symmetrical latching plates (14) which are held in the moulded housing and in which a switching link (18) is supported. Two toggle levers (22) are connected such that they are spaced apart, via a connecting shaft (12) which engages in cam slots in lateral rails. A toggle-lever spring (24) engages between the switching link (18) and the connecting shaft (12). A supporting lever (20) which can be driven by the switching link (18) is supported in a force-fitting manner in the latching plates (14), and the toggle levers (22) are supported in a force-fitting manner in the supporting lever (20). A catch lever (28) and a catch (26) which holds said lever in the locked position are held in a force-fitting manner, by means of a catch spring (30), in recesses (70; 74) in the latching plates (14). <IMAGE>

Description

The invention relates to a switch lock for a performance scarf ter according to the preamble of claim 1. A switch lock as the mechanical link provided with an energy store manual operation or power drive and contact apparatus switching on and off as well as free triggering when opening occurrence of overcurrents.

A known from DE-OS 38 12 950, in a molded housing of Circuit breaker stored switch lock contains one over a Handle operated shift gate, which in a U-shaped Support frame is pivotally mounted, one via a fastening block hinged in the support frame and on both sides with this articulated toggle lever, at the end of which a roller is appropriate. The roller serves to pivot a contact arm load-bearing cross rail over cross rail cam slots and the same early enough to engage two toggle springs loaded under tension, which are attached to the shifting gate and as an energy store Act. On the open side of the support frame is a side frame mounted in which both a ratchet lever and one can be pivoted Pawl and a leaf-shaped pawl spring are stored. in the the support lever is switched on and in the switched off state locked by a hook through the ratchet lever, which is on the other hand by means of appropriately trained latching surfaces is latched by the jack. Is by a thermal or a magnetic overcurrent release a pivoting of the pawl then the latching surfaces are released. Under the force of the toggle springs is then the Klin lever, the support lever unlocked with it, the toggle lever and the Gear shift in the triggered, d. H. in the contact opening, Condition tilted. After eliminating the triggering cause, this can Key switch latched again via the switched-off position or locked and switched on.  

The disadvantage of this known solution is that the manufacturer is too high effort. This results in particular from the requirement the side frame and the mounting block, which as well to produce the pawl in a complex manner as die-cast parts are; continue from the need for many support means such as Rivet bolts for the connection between support lever and toggle lever, Pivots for the support lever, side frame and pawl as well as dowel pin and guide hole for the mounting block; such as from the use of the elaborate actuating roller, the special latch spring to be trained and two toggle springs. A wide one rer significant disadvantage is that in the case of contact welding there is a risk that the contact apparatus despite Triggering the key switch does not open.

According to DE 38 02 184 C2 a switch lock is known, the between two symmetrical to each other, fastened in a molded housing Lock plates is arranged. There is a shift gate pivoted in the lock plates. A support lever is open a support axis mounted in the lock plates. A Lift mechanism engages between the shift gate and the end Connection axis of two toggle levers that are in contact with their support the other end against a bolt attached to the support lever. Knee joint straps couple the connection axis with a Cross rail axis. Locking tabs are still in the support axis stored, on the one hand via a driving pin with backdrops the shift gate are coupled and on the other hand by concerns certain points of contact in connection with the toggle levers are feasible. A pawl actuated by the triggers and a through this to be latched, releasing the support lever in the event of overcurrent Pawl levers are mounted axially in the lock plates.

This switch lock requires a high level of manufacture Manufacturing effort, on the one hand from the high number of necessary Parts and on the other hand from the elaborate and complicated Assembly technology with long handcrafting times for the general Mostly to be inserted laterally into the lock plates parts to be fastened therein, especially the numerous ones Axes.

It is therefore an object of the invention to ensure reliable contact Apparatus opening switch lock to show that less and there are technologically simpler individual parts.

This object is achieved by a contact system with the Characteristic of claim 1 solved. The proposed switching castle consists of fewer elements compared to the prior art which, however, largely fulfill several functions. These can be done in a technologically advantageous manner with simple Joining movements mounted in each other and between the lock plates be, moving laterally through the lock plates and under the influence of the toggle spring and the pawl spring are held essentially non-positively. The assembly of the Key switch comes without the use of complex connec processes such as welding or riveting.

Further advantageous embodiments of the con clock systems can be found in claims 2 to 16. The cones on the lock plates and the wraps on the support lever are also like the first and second end faces and stop faces of the Toggle lever or support lever as well as the knee and support lever abutments particularly advantageous means to those concerned  Elements of the key switch to fit together and under the Action of the toggle spring against each other in pivotable Hold positions. The shift gate, the support lever, the knees lever and toggle spring form a simple, but in front geous way very quickly in the triggered state existing jump mechanism. The movement in the triggered state can be done in a simple and effective manner by means of the stop angle on the lock plates and the lugs on the support lever limit. The third end faces and stop faces generate the toggle levers or on the shift gate when welded leverage during switching off, which breaks these contacts. The same effect is achieved during the Transition to the triggered state through the interaction of the fourth end face reached with the third stop face. The Guide lugs on the support lever allow a simple one and we kung lateral guidance of the toggle lever in the support lever, the limitation form an additional securing of the position Toggle lever represents against the high forces that occur when switching lock movements with initially welded contact pieces occur. A helical pawl spring is a particularly cheap one Standard part. This allows the latch and the latch lever against each other non-positively by means of the jack and jack marriage Pad formings in the associated ratchet or ratchet lever Hold recesses in which they previously in a simple way have been set. An essentially triangular formation these recesses and the handle configuration are special simple means of achieving this advantage. To the relieving The pawl hole and the pawl lever hole are used for assembly or in a particularly advantageous manner, the hook-shaped instead Training on pawl and pawl lever. The ratchet lever nose on the latch lever and the associated sliding surface on the latch cause the latch lever to latch faster and make it easier tern to a considerable extent the possible power drive of the Switch lock via a motor.

The invention will be explained in more detail using an exemplary embodiment are explained. In the accompanying drawing shows

Figure 1 shows a switch lock according to the invention with an associated contact apparatus in a partial exploded view.

Figure 2 shows a part of the key switch in partial Explosionsdar position, seen from the side from the side.

Fig seen 3 is a further exploded view of the switch latch laterally from behind.

Figure 4 is a side view of the switching mechanism with the associated contact system in the off state.

Fig. 5 is as Figure 4, but in the ON state.

Fig. 6 as Figure 4, but in the tripped state.

Fig. 7 as Fig. 4, but with welded contact pieces.

In Fig. 1, a switch lock 10 according to the Invention and a device operated by this contact with three contact systems 8 are shown as part of a circuit breaker. Each Kontakttsy stem 8 contains an immobile contact carrier 1 with a welded on stationary contact piece 2 and a movable contact arm 3 with a welded-on movable contact piece 4th The contact arms 3 are resiliently mounted in a cross rail 5 on which two cams 6 are formed radially. Cam slots 7 serve to receive a connecting axis 12 of the switch lock 10 and thus the movement transmission from the switch lock 10 to the contact apparatus. The contact carrier 1 and the cross rail 5 are embedded or stored in a usual manner in a mold housing, not shown. The switching lock 10 has two lateral, mirror-symmetrical lock plates 14 . Their position is fixed by inner side surfaces of the molded housing and by end-side, L-shaped fastening lugs 16 which are screwed to the bottom of the molded housing by means of two fastening screws 17 guided into the molded housing from below.

According to Fig. 2 and 3, the switching mechanism of the two lock plates 14, a switching gate 18, a support lever 20, two toggle levers 22, the connecting axis 12, a helical toggle spring 24, a pawl 26, a pawl lever 28 and a pawl spring 30.

The switching link 18 is substantially U-shaped and has a connecting web 38 with an angle 40 for BEFE stigung a handle, not shown, and two side legs 39 . With leg ends 32, the shift gate is the lock plates 14 Gert 18 from above in the bearing sections 34 pivotally gela, wherein the pivotal movement of cutouts in each case by a front and a rear frontal boundary surface 36 and 37 of the bearing is limited 34th The U-shaped support lever 20 is pivotally supported upward against the force of the toggle spring 24 by means of two grips 42 formed on its side walls 41 from two pins 44 , each of which is located on the inside of each lock plate 14 . The side walls 41 of the support lever 20 are formed the front side such that it is limited in the released position by means of its lugs 45 with inwardly bent stop bracket 46 of the lock plates 14 in its pivotal movement and also genes inside gebo entrainment angle 48 on the legs 39 of the shifting gate 18 can be moved from the triggered to the off position.

The two-leg toggle levers 22 are of identical design and are connected at one end via the connecting axis 12 and kept at a distance. The toggle lever spring 24 engages by means of an eyelet 50 in the middle of the connecting axis 12 and on a transverse web 52 within a fastening slot 53 in the connecting web 38 of the shifting gate 18 . The toggle levers 22 are supported in the support lever 20 against the force of the toggle spring 24 . For this purpose, the toggle levers 22 each have a first end face 54 for the switched-off and a second end face 56 for the switched-on state. An arcuate toggle abutment 58 is located at a distance between the two end faces 54 and 56 . The toggle lever abutment 58 is supported in more open bogenför shaped support lever abutments 60 , which are formed in open recesses in the side walls 41 of the support lever 20 and to which one of the first end faces 54, corresponding to the first stop face 62 and one of the second end faces 56, speaks accordingly Connect second stop surface 64 . The shifting gate 18 , the support lever 20 , the toggle lever 22 and the toggle spring 24 form a simple but very effective toggle mechanism. The tilt angle of the toggle levers 22 is determined by the amount by which the inner angle between the first and second stop surfaces 62 and 64 is greater than the outer angle between the first and second end faces 54 and 56 . In the overstretched state of the toggle mechanism, ie with the greatest expansion of the Kniehebelfe of the 24 in an intermediate position between the switched-off and the switched-on state of the switching mechanism 10 , the points of contact of the toggle abutment 58 with the Stützhebelwi derlagern 60 are in one plane with the points of application of the toggle spring 24 on the switching link 18 or on the connecting axis 12 . The toggle 22 spaced held by the connecting shaft 12 are guided laterally by each one of the side walls 41 of the support lever 20 shaped guide nose 66th

The pawl 26 has laterally triangular prismatic pawl support formations 68 , with which they are pivotally mounted from above in triangular pawl support recesses 70 , which are located in the lock plates 14 on the side facing away from the contact systems 8 (see FIG. 1). The Klinkenhe bel 28 has laterally formed ratchet lever support formations 72 , with which it is pivotally supported from below in triangularly shaped ratchet lever support recesses 74 , which are located in the lock plates 14 below the ratchet support recesses 70 . The helical pawl spring 30 is suspended with eyelets 76 under a slight tension in an associated pawl bore 77 and an associated pawl lever bore 78 , whereby the pawl 26 and the pawl lever 28 are held in the lock plates 14 . The pawl bore 77 is located in a nose-like first projection 79 of the pawl 26 below the pawl carrying recesses 68 .

An upwardly directed, first locking surface 80 is in a rectangular recess which is open at the rear 21 of the Stützhe bels 20 in the off and on state of the switching mechanism 10 in operative connection with a downward, the second locking surface 82 in a rectangular enclosed recess 84 the ratchet lever 28 . On the latch lever 28 , a downward-facing, first latching surface 86 is formed above the recess 84 in a rectangular, open notch, which in the switched-off and in the switched-on state is operatively connected to a second latching surface 88 , which is formed on the first projection 79 of the latch 26 is. The first latching surface 86 and the second latching surface 88 bring about a positive latching between the latch 26 and the latch lever 28 , which in turn, under the action of the toggle spring 24 , maintains the latch between the latch lever 28 and the support lever 20 , so that the switching mechanism 10 remains excited. The pawl 26 has a trigger surface 90 above the pawl support formations 68 , which receives the triggering movement of a magnetic or thermal trigger (not shown). From the upper part of the pawl lever 28 to the pawl 26 an angled lever nose 92 is angled, which comes into operative connection during the transition from the released to the locked state with a sliding surface 94 , which is formed upward on a second projection 96 of the pawl 26 , whereby the quick locking and latching is facilitated as a result of greater pretensioning of the pawl spring 30 .

In the off state of the switching mechanism 10 of FIG. 4, ie, by opening the contact system 8, there are the Kniehe belwiderlager 58 and the supporting lever abutment 60 to the left of the line connecting the engagement points of the toggle spring 24. The support lever 20 is locked on the first locking surface 80 by the pawl lever 28 , which in turn is latched on the first Ver latching surface 86 by the pawl 26 and the pawl spring 30 and is thus held in the locking position. In the on state of the switching mechanism 10 of FIG. 5, that is, by closing the contact system 8, there are the toggle lever abutment 58 and the supporting lever abutment 60 on the right of the line connecting the engagement points of the toggle spring 24. The support lever 20 , the pawl lever 28 and the pawl 26 are in the same positions as in the switched-off state according to FIG. 4.

In Fig. 6, the triggered state of the key switch 10 is Darge, in which the contact systems 8 normally pass into the open state. The triggered state has been brought about by the force acting on the left on the trigger surface 90 of the pawl 26 and generated by the trigger in the event of an overcurrent. As a result, the pawl 26 and the pawl lever 28 have been unlatched from one another, which has resulted in a sudden relaxation of the switching mechanism 10 by the release of the locking surface 80 of the support lever 20 . From Fig. 6, the movement limitation of the support lever 20 described above in the counterclockwise direction by the interaction of the lugs 45 of the support lever 20 with the stop angles 46 of the lock plates 14 (see also FIG. 2) can be seen. If, after the disappearance or elimination of the triggering cause, the switching link 18 is pivoted clockwise into the off position, then the support lever 20 is pivoted in the same sense by the entrainment 48 . The ratchet lever nose 92 slides along the back 21 of the support lever 20 (see FIG. 3). Due to the pivotal movement of the pawl lever 28 generated in the clockwise direction, the first locking surface 80 on the support lever 20 comes again under the second locking surface 82 on the pawl lever 28 , which in turn is latched by the pawl 26 .

From Fig. 2 it can also be seen that a third stop surface 98 is formed at an angle on the legs 39 of the shifting gate 18 , which corresponds to a notched, third end surface 97 on the toggle levers 22 , which corresponds to the second end surface 56 on the same side, however, is located somewhat closer to the toggle abutment 58 . As shown in FIG. 7, when switching off via the switching link 18, the third stop surface 98 and the third end face 97 meet in the case of welded contact pieces 2 and 4 , so that after the overstretched state of the toggle spring 24 on the toggle lever 22 a leverage effect in Counterclockwise with the toggle abutment 58 is exercised as a fulcrum, which with sufficient leverage for breaking open and subsequent opening of the contact pieces 2 and 4 leads. On the toggle levers 22 , on the side of the third end face 97 in closer with respect to the second end face 56 , but with respect to the third end face further distance from the toggle lever abutment 58, a fourth end face 99 is formed, which in cooperation with the third stop surface 98 is similar to that in FIG The manner described above for breaking welded contact pieces 2 and 4 is used in the transition to the triggered state. On each toggle lever 22 , an inwardly extending, pin-shaped limiting shape 95 is provided, which in the case of strongly welded contact pieces 2 and 4 comes to rest against the associated guide tab 66 on the support lever 20 . The storage of the toggle levers 22 in the support lever 20 is thus additionally secured.

Claims (15)

1. Switch latch for a circuit breaker disposed between two successive symmetrical, retained in a mold housing lock plates (14), connected to a contact arm (3) supporting cross rail (5), containing a switching gate (18), a pivotable support lever (20), two symmetrical toggle levers ( 22 ) which are connected at one end by a connecting axis ( 12 ) and at the other end against the force of an energy accumulator which acts between the shifting link ( 18 ) and the connecting axis ( 12 ) against the supporting lever ( 20 ) pivotally supported, further comprising a pawl ( 26 ) which can be actuated by triggers and a pawl lever ( 28 ) which can be latched by this and which in turn locks the support lever ( 20 ) in the non-released state, characterized by the following features:

• - The switching lock ( 10 ) can be inserted between the lock plates ( 14 ) and by means of a support pin ( 44 ) on the inside of the lock plates ( 14 ) and a correspondingly designed open grip ( 42 ) on the side walls ( 41 ) of the support lever ( 20 ) non-positively held,
• - The support lever ( 20 ) can be taken directly through the shifting gate ( 18 ),
• - The connecting axis ( 12 ) engages with cam slots ( 7 ) of the cross rail ( 5 ),
• - The energy accumulator consists of only one toggle spring ( 24 ),
• - The toggle levers ( 22 ) are supported in the side walls ( 41 ) of the support lever ( 20 ),
• - The pawl ( 26 ) and the pawl lever ( 28 ) can be inserted into the lock plates ( 14 ) and are held against each other in this by the force of a pawl ( 26 ) and pawl lever ( 28 ) engaging pawl spring ( 30 ).

2. Switch lock according to claim 1, characterized by

• - In each case on the toggle levers ( 22 ) formed first end faces ( 54 ) for the switched-off state, second end faces ( 56 ) for the switched-on state and between these end faces ( 54; 56 ) spaced arcuate toggle lever bearings ( 58 ),
• - In each case recesses in the side walls ( 41 ) of the support lever ( 20 ) corresponding to the first and second end faces ( 54 ; 56 ) formed first and second stop surfaces ( 62 ; 64 ) and between these arcuate support lever abutment ( 60 ),
• - a larger opening angle of the support lever abutment ( 60 ) compared to the toggle lever abutment ( 58 ),
• - A flat intermediate layer of the contacting abutments ( 58 ; 60 ) between the points of application of the toggle lever spring ( 24 ) in the overstretched state.

3. Switch lock according to one of claims 1 or 2, characterized by

• - In each case one on the side facing away from the latch lever ( 28 ) of the lock plates ( 14 ) inwardly bent stop angle ( 46 ),
• - Each in the triggered state with this end stop ( 45 ) on the side walls ( 41 ) of the support lever ( 20 ).

4. Switch lock according to one of claims 1 to 3, characterized by

• - A third stop surface ( 98 ) formed in each case on the side legs ( 39 ) of the switching link ( 18 ),
• - On the toggle levers ( 22 ) accordingly formed third end face ( 97 ), which extends on the sides and at a distance from the second end face ( 56 ),
• - When switching off after exceeding the overstretched state of the toggle spring ( 24 ), the third stop surfaces ( 98 ) and the third end faces ( 97 ) can be brought into operative connection in the sense of a contact separation.

5. Switch lock according to claim 4, characterized by

• a fourth end face ( 99 ) formed on the toggle levers ( 22 ) and located at a further distance from the toggle lever bearing ( 58 ) with respect to the third end face ( 97 ),
• - The third stop faces ( 98 ) and the fourth end faces ( 99 ) can be brought into operative connection in the sense of a contact separation when triggered.

6. Switch lock according to one of claims 1 to 5, characterized by

• - Each on the side walls ( 41 ) of the support lever ( 20 ) inwardly shaped, for the toggle lever ( 22 ) provided Füh approximately ( 66 ) near the support lever abutment ( 60 ).

7. Switch lock according to claim 6, characterized by

• - In each case an inwardly extending limiting shape ( 95 ) on the toggle levers ( 22 ) which can be brought to bear against the associated guide lug ( 66 ).

8. Switch lock according to one of claims 1 to 7, characterized by

• - A helical pawl spring ( 30 ).

9. Switch lock according to claim 8, characterized by

• - Notch-shaped pawl carrying recesses ( 70 ) in the lock plates ( 14 ),
• - Corresponding lateral pawl support formations ( 68 ) on the pawl ( 26 ).

10. Switch lock according to claim 9, characterized by

• - A substantially triangular design of the latch support recesses ( 70 ),
• - An essentially triangular prismatic design of the latch support formations ( 72 ).

11. Switch lock according to claim 8, characterized by

• - Notch-shaped pawl lever recesses ( 74 ) in the lock plates ( 14 ),
• - Corresponding lateral pawl lever support formations ( 72 ) on the pawl levers ( 28 ).

12. Switch lock according to claim 11, characterized by

• - A substantially triangular design of the pawl lever recesses ( 74 ).

13. Switch lock according to claim 8, characterized by

• - A fastening of the pawl spring ( 30 ) between a pawl bore ( 77 ) and a pawl lever bore ( 78 ).

14. Switch lock according to claim 8, characterized by

• - An attachment of the pawl spring ( 30 ) between a respective hook-shaped design of the pawl ( 26 ) and the pawl lever ( 28 ).

15. Switch lock according to one of claims 1 to 14, characterized by

• a ratchet lever nose ( 92 ) on the ratchet lever ( 22 ),
• - a corresponding sliding surface ( 94 ) on the pawl ( 26 ),
• - The ratchet lever nose ( 92 ) and the sliding surface ( 94 ) in a ge to increase the bias of the pawl spring ( 30 ) directed active connection can be brought.